CN213100896U - Energy-efficient condensing equipment - Google Patents
Energy-efficient condensing equipment Download PDFInfo
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- CN213100896U CN213100896U CN202020764311.6U CN202020764311U CN213100896U CN 213100896 U CN213100896 U CN 213100896U CN 202020764311 U CN202020764311 U CN 202020764311U CN 213100896 U CN213100896 U CN 213100896U
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Abstract
The utility model relates to an energy-efficient condensing equipment, when using, the gas loops through third condensation zone, second condensation zone and first condensation zone from bottom to top, has effectively improved the condensation efficiency, novel structure, has wide market prospect; the gas of the utility model is gradually condensed in the vertical cold air from bottom to top, and the gas above the gas can directly flow down along one side of the condenser after being condensed into liquid, so as to prevent the condensed liquid from attaching on the subsequent condenser pipe and influencing the condensation effect; the utility model discloses first condensation zone has adopted first snakelike condenser pipe of pivoted, and pivoted snakelike condenser pipe can effectively mix gas, forms the turbulent flow, increases the contact frequency of gas and first snakelike condenser pipe to improve condensing efficiency, and, because first snakelike condenser pipe is in the rotation state, can throw away its surface-attached condensate, thereby guarantee the heat exchange efficiency of first snakelike condenser pipe.
Description
Technical Field
The utility model relates to a condensing equipment technical field, concretely relates to energy-efficient condensing equipment.
Background
A condenser, a component of a refrigeration system, belongs to a heat exchanger, and can convert gas or vapor into liquid to transfer heat in a tube to air near the tube in a quick mode. The condenser operation is exothermic and therefore the condenser temperature is high. In a refrigeration system, an evaporator, a condenser, a compressor and a throttle valve are four essential parts in the refrigeration system, wherein the evaporator is a device for conveying cold. The refrigerant absorbs heat from the cooled object therein to perform cooling. The compressor is a heart and functions to suck, compress, and deliver refrigerant vapor. The condenser is a heat-emitting device, which transfers the heat absorbed in the evaporator to a cooling medium together with the heat converted by the compressor. The throttle valve performs the functions of throttling and depressurizing the refrigerant, simultaneously controls and regulates the amount of refrigerant liquid flowing into the evaporator, and divides the system into two parts, namely a high-pressure side and a low-pressure side. In addition to the four major components, there are usually some auxiliary equipments in the actual refrigeration system, such as solenoid valves, distributors, dryers, heat collectors, fusible plugs, pressure controllers, etc., which are provided to improve the economy, reliability and safety of operation. At present, the existing condenser has poor condensation effect and lower condensation effect. In view of the above disadvantages, it is necessary to design an efficient and energy-saving condensing device.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a high-efficient energy-conserving condensing equipment to solve the problem that proposes in the above-mentioned background art.
In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an energy-efficient condensing equipment, includes the condensation jar, the top of condensation jar is provided with the gas outlet, be equipped with first condensation zone, second condensation zone and third condensation zone in the condensation jar from top to bottom in proper order, first condensation zone includes the first snakelike condenser pipe that the level set up, the both ends of first snakelike condenser pipe pass through the rotatable supporting of bearing on the lateral wall of condensation jar, and the right-hand member overcoat of first snakelike condenser pipe is equipped with driven gear, still be equipped with driving motor outside the right side wall of condensation jar, driving motor's bottom is equipped with the support, and driving motor's motor shaft tip is equipped with drive gear, and drive gear meshes with driven gear mutually.
Preferably, the second condensation area includes first condensing plate and the second condensing plate that sets up from top to bottom, first condensing plate tilt up, the second condensing plate is parallel with ground, is equipped with the snakelike condenser pipe of a plurality of second that are listed as between first condensing plate and the second condensing plate, and the snakelike condenser pipe both ends of second and condensation jar inner chamber intercommunication are equipped with the siphunculus in one side of second condensation area, and the both ends of siphunculus are equallyd divide respectively with condensation jar inner chamber intercommunication, one side of second condensation area is equipped with refrigerant import and refrigerant outlet.
Preferably, the third condensation area comprises a condensation blade, the condensation blade is positioned on the inner side of the condensation tank, a condensation water pipe is installed inside the condensation blade, and a circulation groove is reserved on the condensation blade.
Preferably, the condensing blades are nested on the outer side of the condensing pipe, and the condensing blades are spirally distributed on the inner side of the condensing tank.
Preferably, the condensate pipe coincide with inlet tube and outlet pipe respectively and is connected, and the condensate pipe is the plastics material, condensation blade respectively with inlet tube and outlet pipe interconnect, and inlet tube and water pump interconnect to install the drinking-water pipe on the water pump, condensation blade is the slope structure, and condensation blade and condensate tank are welded connection.
Preferably, the bottom of condensing tank is provided with air inlet and temperature sensor respectively to temperature sensor is located the top of air inlet, the delivery port has been seted up to the bottom of condensing tank, and the below of delivery port installs the filter ring to the inboard of filtering the ring is provided with the filter screen, filters ring and delivery port threaded connection, and filters ring and filter screen formula structure as an organic whole.
Preferably, a controller is installed on the outer side of the condensation tank and electrically connected with the temperature sensor.
Compared with the prior art, the high-efficiency energy-saving condensing device has the advantages that when the condensing device is used, gas sequentially passes through the third condensing area, the second condensing area and the first condensing area from bottom to top, so that the condensing efficiency is effectively improved, the structure is novel, and the market prospect is wide; the gas of the utility model is gradually condensed in the vertical cold air from bottom to top, and the gas above the gas can directly flow down along one side of the condenser after being condensed into liquid, so as to prevent the condensed liquid from attaching on the subsequent condenser pipe and influencing the condensation effect; the utility model discloses first condensation zone has adopted first snakelike condenser pipe of pivoted, and pivoted snakelike condenser pipe can effectively mix gas, forms the turbulent flow, increases the contact frequency of gas and first snakelike condenser pipe to improve condensing efficiency, and, because first snakelike condenser pipe is in the rotation state, can throw away its surface-attached condensate, thereby guarantee the heat exchange efficiency of first snakelike condenser pipe.
Drawings
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description, do not constitute a limitation of the invention, in which:
FIG. 1 is a schematic structural view of an energy-efficient condensing unit of the present invention;
fig. 2 is a schematic view of a structure of a condensing blade in an energy-efficient condensing device of the present invention.
In the drawings:
1. a condensing tank; 2. a first condensation zone; 3. a second condensation zone; 4. a third condensation zone; 5. an air outlet; 6. a first serpentine condenser tube; 7. a bearing; 8. a driven gear; 9. a drive motor; 10. a support; 11. a drive gear; 12. a first cold plate; 13. a second cold plate; 14. a second serpentine condenser tube; 15. pipe passing; 16. a refrigerant inlet; 17. a refrigerant outlet; 18. a condensing blade; 19. a condensate pipe; 20. a water inlet pipe; 21. a water outlet pipe; 22. a water pump; 23. a water pumping pipe; 24. an air inlet; 25. a temperature sensor; 26. a water outlet; 27. a filter ring; 28. a filter screen; 29. a controller; 30. and (4) a circulating groove.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1, the present invention provides a technical solution: the utility model provides an energy-efficient condensing equipment, includes condensation jar 1, the top of condensation jar 1 is provided with gas outlet 5, be equipped with first condensation zone 2, second condensation zone 3 and third condensation zone 4 from top to bottom in the condensation jar 1 in proper order, first condensation zone 2 includes the first snakelike condenser pipe 6 that the level set up, the rotatable supporting of bearing 7 is passed through at the both ends of first snakelike condenser pipe 6 on the lateral wall of condensation jar 1, and the right-hand member overcoat of first snakelike condenser pipe 6 is equipped with driven gear 8, still be equipped with driving motor 9 outside the right side wall of condensation jar 1, driving motor 9's bottom is equipped with support 10, and driving motor 9's motor shaft tip is equipped with drive gear 11, and drive gear 11 meshes with driven gear 8 mutually.
In this embodiment second condensation zone 3 is including the first cold plate 12 and the second cold plate 13 that set up from top to bottom, first cold plate 12 tilt up, second cold plate 13 is parallel with ground, be equipped with the snakelike condenser pipe 14 of a plurality of second that are listed as between first cold plate 12 and the second cold plate 13, the snakelike condenser pipe 14 both ends of second and 1 inner chamber intercommunication of condensing tank, one side of second condensation zone 3 is equipped with siphunculus 15, 15 both ends of siphunculus are equallyd divide respectively with 1 inner chamber intercommunication of condensing tank, one side of second condensation zone 3 is equipped with refrigerant inlet 16 and refrigerant outlet 17.
In this embodiment, the third condensation area 4 includes a condensation blade 18, the condensation blade 18 is located inside the condensation tank 1, a condensation pipe 19 is installed inside the condensation blade 18, a circulation groove 30 is reserved on the condensation blade 18, the condensation blade 18 is nested outside the condensation pipe 19, the condensation blade 18 is distributed spirally inside the condensation tank 1, so as to conveniently block and condense the diffused gas, the condensation pipe 19 is respectively connected with the water inlet pipe 20 and the water outlet pipe 21 in an inosculating manner, the condensation pipe 19 is made of plastic material, the service life of the condensation pipe 19 is prolonged, the condensation blade 18 is respectively connected with the water inlet pipe 20 and the water outlet pipe 21, the water inlet pipe 20 is connected with the water pump 22, the water pumping pipe 23 is installed on the water pump 22, the condensation blade 18 is of an inclined structure, and the condensation blade 18 is connected with the condensation tank 1 in a welding manner, so as to guide the moisture generated by condensation, the bottom of condensation jar 1 is provided with air inlet 24 and temperature sensor 25 respectively to temperature sensor 25 is located the top of air inlet 24, delivery port 26 has been seted up to the bottom of condensation jar 1, and the below of delivery port 26 installs filter ring 27, and the inboard of filtering ring 27 is provided with filter screen 28, filters ring 27 and delivery port 26 threaded connection, and filters ring 27 and filter screen 18 structure as an organic whole, conveniently dismantles the clearance to filtering ring 27, and controller 29 is installed in the outside of condensation jar 1, controller 29 and temperature sensor 25 electric connection.
In order to prevent the liquid drops formed by the condensed gas from flowing along the first condensation plate 12 and flowing into the second serpentine-shaped condensation pipe 14, the upper pipe opening of the second serpentine-shaped condensation pipe 14 of the third condensation area 4 is higher than the upper surface of the first condensation plate 12.
The working principle is as follows: during condensation, gas enters the third condensation area 4 of the condensation tank 1 from the gas inlet 24, when the gas enters the condensation tank 1, the temperature sensor 25 above the gas inlet 24 detects temperature rise, then the temperature sensor 25 transmits a signal to the controller 29, the controller 29 controls the water pump 22 to start working, the water pump 22 pumps cooling water through the water pumping pipe 23, then the cooling water is input into the condensation water pipe 19 in the condensation blade 18 through the water inlet pipe 20, the gas is blocked by the condensation blade 18 in the upward scattering process, the gas is contacted with the condensation blade 18, at the moment, the cooling water in the condensation water pipe 19 cools the gas through the condensation blade 18, moisture generated by temperature reduction flows downwards along the inclined condensation blade 18 and the inner wall of the condensation tank 1, then the moisture flows into the circulation groove 30, and the moisture flows to the bottom end of the condensation tank 1 through the condensation groove 30, moisture is discharged through a water outlet 26 at the bottom end of the condensing tank 1, the water scale in the moisture is filtered by a filter ring 27 and a filter screen 28, other condensed gas enters the second condensing area 3, after the gas enters the second serpentine condenser pipe 14, the gas in the second serpentine condenser pipe 14 exchanges heat with condensate outside the second serpentine condenser pipe 14, condensed liquid flows out from a pipe outlet of the second serpentine condenser pipe 14 and finally drops into the water outlet 26 at the bottom of the condensing tank 1, uncondensed gas continues to enter the first condensing area 2, the first condensing area 2 adopts the rotating first serpentine condenser pipe 6, the rotating serpentine condenser pipe can effectively stir the gas to form turbulence, the contact frequency of the gas and the first serpentine condenser pipe 6 is increased, so that the condensing efficiency is improved, and the condensate attached to the surface of the first serpentine condenser pipe 6 can be thrown away due to the first serpentine condenser pipe 6 being in a rotating state, thereby ensuring the heat exchange efficiency of the first serpentine-shaped condensation duct 6.
When the utility model is used, the gas sequentially passes through the third condensation zone 4, the second condensation zone 3 and the first condensation zone 2 from bottom to top, thereby effectively improving the condensation efficiency, having novel structure and wide market prospect; the gas is gradually condensed in the vertical cold air from bottom to top, and the gas above the gas is directly flowed down along one side of the condenser after being condensed into liquid, so that the condensed liquid is prevented from being attached to a subsequent condenser pipe to influence the condensation effect; first condensing zone 2 has adopted first snakelike condenser pipe 6 of pivoted, and the snakelike condenser pipe of pivoted can effectively stir gas, forms the turbulent flow, increases gaseous and first snakelike condenser pipe 6's contact frequency to improve condensing efficiency, and, because first snakelike condenser pipe 6 is in the rotation state, can throw away its surface-attached condensate, thereby guarantee first snakelike condenser pipe 6's heat exchange efficiency.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (1)
1. The utility model provides an energy-efficient condensing equipment, includes condensing tank (1), its characterized in that: the top of the condensing tank (1) is provided with an air outlet (5), the condensing tank (1) is internally provided with a first condensation area (2), a second condensation area (3) and a third condensation area (4) from top to bottom in sequence, the first condensation area (2) comprises a first snakelike condensation pipe (6) horizontally arranged, two ends of the first snakelike condensation pipe (6) are rotatably supported on the side wall of the condensing tank (1) through bearings (7), a driven gear (8) is sleeved outside the right end of the first snakelike condensation pipe (6), a driving motor (9) is further arranged outside the right side wall of the condensing tank (1), the bottom of the driving motor (9) is provided with a support (10), the end part of a motor shaft of the driving motor (9) is provided with a driving gear (11), the driving gear (11) is meshed with the driven gear (8), the second condensation area (3) comprises a first condensation plate (12) and a second condensation plate (13) which are arranged from top to bottom, the utility model discloses a condensing device, including first condensing plate (12) tilt up, second condensing plate (13) are parallel with ground, are equipped with a plurality of second snakelike condenser pipe (14) of row between first condensing plate (12) and second condensing plate (13), and second snakelike condenser pipe (14) both ends and condensing tank (1) inner chamber intercommunication, and one side of second condensing zone (3) is equipped with siphunculus (15), and the both ends of siphunculus (15) are equallyd divide and do not communicate with condensing tank (1) inner chamber, one side of second condensing zone (3) is equipped with refrigerant import (16) and refrigerant export (17), third condensing zone (4) are including condensing blade (18), condensing blade (18) are located the inboard of condensing tank (1), and the internally mounted of condensing blade (18) has condensing pipe (19) to condensing blade (18) are last to reserve circulation groove (30), condensing blade (18) nestification is in the outside of condensing pipe (19), and condensation blade (18) are the heliciform and distribute in the inboard of condensation jar (1), condensate pipe (19) coincide with inlet tube (20) and outlet pipe (21) respectively and are connected, and condensate pipe (19) are the plastics material, condensation blade (18) respectively with inlet tube (20) and outlet pipe (21) interconnect, and inlet tube (20) and water pump (22) interconnect, and install drinking-water pipe (23) on water pump (22), condensation blade (18) are the slope structure, and condensation blade (18) and condensation jar (1) are welded connection, the bottom of condensation jar (1) is provided with air inlet (24) and temperature sensor (25) respectively, and temperature sensor (25) are located the top of air inlet (24), delivery port (26) have been seted up to the bottom of condensation jar (1), and filter ring (27) are installed to the below of delivery port (26), and the inboard of filtering ring (27) is provided with filter screen (28), filters ring (27) and delivery port (26) threaded connection, and filters ring (27) and filter screen (28) and be the integral structure, controller (29) is installed to the outside of condensation jar (1), controller (29) and temperature sensor (25) electric connection.
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CN202020764311.6U CN213100896U (en) | 2020-05-11 | 2020-05-11 | Energy-efficient condensing equipment |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202020764311.6U CN213100896U (en) | 2020-05-11 | 2020-05-11 | Energy-efficient condensing equipment |
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CN213100896U true CN213100896U (en) | 2021-05-04 |
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CN202020764311.6U Active CN213100896U (en) | 2020-05-11 | 2020-05-11 | Energy-efficient condensing equipment |
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